base/files/file_path.cc - third_party/gn - Git at Google

 // Copyright (c) 2012 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "base/files/file_path.h"

 #include <string.h>
 #include <algorithm>

 #include "base/logging.h"
 #include "base/macros.h"
 #include "base/strings/string_piece.h"
 #include "base/strings/string_util.h"
 #include "base/strings/utf_string_conversions.h"
 #include "util/build_config.h"

 #if defined(OS_MACOSX)
 #include "base/mac/scoped_cftyperef.h"
 #include "base/third_party/icu/icu_utf.h"
 #endif

 #if defined(OS_WIN)
 #include <windows.h>
 #elif defined(OS_MACOSX)
 #include <CoreFoundation/CoreFoundation.h>
 #endif

 namespace base {

 using StringType = FilePath::StringType;
 using StringPieceType = FilePath::StringPieceType;

 namespace {

 const char* const kCommonDoubleExtensionSuffixes[] = {"gz", "z", "bz2", "bz"};
 const char* const kCommonDoubleExtensions[] = {"user.js"};

 const FilePath::CharType kStringTerminator = FILE_PATH_LITERAL('\0');

 // If this FilePath contains a drive letter specification, returns the
 // position of the last character of the drive letter specification,
 // otherwise returns npos.  This can only be true on Windows, when a pathname
 // begins with a letter followed by a colon.  On other platforms, this always
 // returns npos.
 StringPieceType::size_type FindDriveLetter(StringPieceType path) {
 #if defined(FILE_PATH_USES_DRIVE_LETTERS)
   // This is dependent on an ASCII-based character set, but that's a
   // reasonable assumption.  iswalpha can be too inclusive here.
   if (path.length() >= 2 && path[1] == L':' &&
       ((path[0] >= L'A' && path[0] <= L'Z') ||
        (path[0] >= L'a' && path[0] <= L'z'))) {
     return 1;
   }
 #endif  // FILE_PATH_USES_DRIVE_LETTERS
   return StringType::npos;
 }

 #if defined(FILE_PATH_USES_DRIVE_LETTERS)
 bool EqualDriveLetterCaseInsensitive(StringPieceType a, StringPieceType b) {
   size_t a_letter_pos = FindDriveLetter(a);
   size_t b_letter_pos = FindDriveLetter(b);

   if (a_letter_pos == StringType::npos || b_letter_pos == StringType::npos)
     return a == b;

   StringPieceType a_letter(a.substr(0, a_letter_pos + 1));
   StringPieceType b_letter(b.substr(0, b_letter_pos + 1));
   if (!StartsWith(a_letter, b_letter, CompareCase::INSENSITIVE_ASCII))
     return false;

   StringPieceType a_rest(a.substr(a_letter_pos + 1));
   StringPieceType b_rest(b.substr(b_letter_pos + 1));
   return a_rest == b_rest;
 }
 #endif  // defined(FILE_PATH_USES_DRIVE_LETTERS)

 bool IsPathAbsolute(StringPieceType path) {
 #if defined(FILE_PATH_USES_DRIVE_LETTERS)
   StringType::size_type letter = FindDriveLetter(path);
   if (letter != StringType::npos) {
     // Look for a separator right after the drive specification.
     return path.length() > letter + 1 &&
            FilePath::IsSeparator(path[letter + 1]);
   }
   // Look for a pair of leading separators.
   return path.length() > 1 && FilePath::IsSeparator(path[0]) &&
          FilePath::IsSeparator(path[1]);
 #else   // FILE_PATH_USES_DRIVE_LETTERS
   // Look for a separator in the first position.
   return path.length() > 0 && FilePath::IsSeparator(path[0]);
 #endif  // FILE_PATH_USES_DRIVE_LETTERS
 }

 bool AreAllSeparators(const StringType& input) {
   for (StringType::const_iterator it = input.begin(); it != input.end(); ++it) {
     if (!FilePath::IsSeparator(*it))
       return false;
   }

   return true;
 }

 // Find the position of the '.' that separates the extension from the rest
 // of the file name. The position is relative to BaseName(), not value().
 // Returns npos if it can't find an extension.
 StringType::size_type FinalExtensionSeparatorPosition(const StringType& path) {
   // Special case "." and ".."
   if (path == FilePath::kCurrentDirectory || path == FilePath::kParentDirectory)
     return StringType::npos;

   return path.rfind(FilePath::kExtensionSeparator);
 }

 // Same as above, but allow a second extension component of up to 4
 // characters when the rightmost extension component is a common double
 // extension (gz, bz2, Z).  For example, foo.tar.gz or foo.tar.Z would have
 // extension components of '.tar.gz' and '.tar.Z' respectively.
 StringType::size_type ExtensionSeparatorPosition(const StringType& path) {
   const StringType::size_type last_dot = FinalExtensionSeparatorPosition(path);

   // No extension, or the extension is the whole filename.
   if (last_dot == StringType::npos || last_dot == 0U)
     return last_dot;

   const StringType::size_type penultimate_dot =
       path.rfind(FilePath::kExtensionSeparator, last_dot - 1);
   const StringType::size_type last_separator = path.find_last_of(
       FilePath::kSeparators, last_dot - 1, FilePath::kSeparatorsLength - 1);

   if (penultimate_dot == StringType::npos ||
       (last_separator != StringType::npos &&
        penultimate_dot < last_separator)) {
     return last_dot;
   }

   for (size_t i = 0; i < arraysize(kCommonDoubleExtensions); ++i) {
     StringType extension(path, penultimate_dot + 1);
     if (LowerCaseEqualsASCII(extension, kCommonDoubleExtensions[i]))
       return penultimate_dot;
   }

   StringType extension(path, last_dot + 1);
   for (size_t i = 0; i < arraysize(kCommonDoubleExtensionSuffixes); ++i) {
     if (LowerCaseEqualsASCII(extension, kCommonDoubleExtensionSuffixes[i])) {
       if ((last_dot - penultimate_dot) <= 5U &&
           (last_dot - penultimate_dot) > 1U) {
         return penultimate_dot;
       }
     }
   }

   return last_dot;
 }

 // Returns true if path is "", ".", or "..".
 bool IsEmptyOrSpecialCase(const StringType& path) {
   // Special cases "", ".", and ".."
   if (path.empty() || path == FilePath::kCurrentDirectory ||
       path == FilePath::kParentDirectory) {
     return true;
   }

   return false;
 }

 }  // namespace

 FilePath::FilePath() = default;

 FilePath::FilePath(const FilePath& that) = default;
 FilePath::FilePath(FilePath&& that) noexcept = default;

 FilePath::FilePath(StringPieceType path) {
   path_.assign(path);
   StringType::size_type nul_pos = path_.find(kStringTerminator);
   if (nul_pos != StringType::npos)
     path_.erase(nul_pos, StringType::npos);
 }

 FilePath::~FilePath() = default;

 FilePath& FilePath::operator=(const FilePath& that) = default;

 FilePath& FilePath::operator=(FilePath&& that) = default;

 bool FilePath::operator==(const FilePath& that) const {
 #if defined(FILE_PATH_USES_DRIVE_LETTERS)
   return EqualDriveLetterCaseInsensitive(this->path_, that.path_);
 #else   // defined(FILE_PATH_USES_DRIVE_LETTERS)
   return path_ == that.path_;
 #endif  // defined(FILE_PATH_USES_DRIVE_LETTERS)
 }

 bool FilePath::operator!=(const FilePath& that) const {
 #if defined(FILE_PATH_USES_DRIVE_LETTERS)
   return !EqualDriveLetterCaseInsensitive(this->path_, that.path_);
 #else   // defined(FILE_PATH_USES_DRIVE_LETTERS)
   return path_ != that.path_;
 #endif  // defined(FILE_PATH_USES_DRIVE_LETTERS)
 }

 // static
 bool FilePath::IsSeparator(CharType character) {
   for (size_t i = 0; i < kSeparatorsLength - 1; ++i) {
     if (character == kSeparators[i]) {
       return true;
     }
   }

   return false;
 }

 void FilePath::GetComponents(std::vector<StringType>* components) const {
   DCHECK(components);
   if (!components)
     return;
   components->clear();
   if (value().empty())
     return;

   std::vector<StringType> ret_val;
   FilePath current = *this;
   FilePath base;

   // Capture path components.
   while (current != current.DirName()) {
     base = current.BaseName();
     if (!AreAllSeparators(base.value()))
       ret_val.push_back(base.value());
     current = current.DirName();
   }

   // Capture root, if any.
   base = current.BaseName();
   if (!base.value().empty() && base.value() != kCurrentDirectory)
     ret_val.push_back(current.BaseName().value());

   // Capture drive letter, if any.
   FilePath dir = current.DirName();
   StringType::size_type letter = FindDriveLetter(dir.value());
   if (letter != StringType::npos) {
     ret_val.push_back(StringType(dir.value(), 0, letter + 1));
   }

   *components = std::vector<StringType>(ret_val.rbegin(), ret_val.rend());
 }

 bool FilePath::IsParent(const FilePath& child) const {
   return AppendRelativePath(child, nullptr);
 }

 bool FilePath::AppendRelativePath(const FilePath& child, FilePath* path) const {
   std::vector<StringType> parent_components;
   std::vector<StringType> child_components;
   GetComponents(&parent_components);
   child.GetComponents(&child_components);

   if (parent_components.empty() ||
       parent_components.size() >= child_components.size())
     return false;

   std::vector<StringType>::const_iterator parent_comp =
       parent_components.begin();
   std::vector<StringType>::const_iterator child_comp = child_components.begin();

 #if defined(FILE_PATH_USES_DRIVE_LETTERS)
   // Windows can access case sensitive filesystems, so component
   // comparisions must be case sensitive, but drive letters are
   // never case sensitive.
   if ((FindDriveLetter(*parent_comp) != StringType::npos) &&
       (FindDriveLetter(*child_comp) != StringType::npos)) {
     if (!StartsWith(*parent_comp, *child_comp, CompareCase::INSENSITIVE_ASCII))
       return false;
     ++parent_comp;
     ++child_comp;
   }
 #endif  // defined(FILE_PATH_USES_DRIVE_LETTERS)

   while (parent_comp != parent_components.end()) {
     if (*parent_comp != *child_comp)
       return false;
     ++parent_comp;
     ++child_comp;
   }

   if (path != nullptr) {
     for (; child_comp != child_components.end(); ++child_comp) {
       *path = path->Append(*child_comp);
     }
   }
   return true;
 }

 // libgen's dirname and basename aren't guaranteed to be thread-safe and aren't
 // guaranteed to not modify their input strings, and in fact are implemented
 // differently in this regard on different platforms.  Don't use them, but
 // adhere to their behavior.
 FilePath FilePath::DirName() const {
   FilePath new_path(path_);
   new_path.StripTrailingSeparatorsInternal();

   // The drive letter, if any, always needs to remain in the output.  If there
   // is no drive letter, as will always be the case on platforms which do not
   // support drive letters, letter will be npos, or -1, so the comparisons and
   // resizes below using letter will still be valid.
   StringType::size_type letter = FindDriveLetter(new_path.path_);

   StringType::size_type last_separator = new_path.path_.find_last_of(
       kSeparators, StringType::npos, kSeparatorsLength - 1);
   if (last_separator == StringType::npos) {
     // path_ is in the current directory.
     new_path.path_.resize(letter + 1);
   } else if (last_separator == letter + 1) {
     // path_ is in the root directory.
     new_path.path_.resize(letter + 2);
   } else if (last_separator == letter + 2 &&
              IsSeparator(new_path.path_[letter + 1])) {
     // path_ is in "//" (possibly with a drive letter); leave the double
     // separator intact indicating alternate root.
     new_path.path_.resize(letter + 3);
   } else if (last_separator != 0) {
     // path_ is somewhere else, trim the basename.
     new_path.path_.resize(last_separator);
   }

   new_path.StripTrailingSeparatorsInternal();
   if (!new_path.path_.length())
     new_path.path_ = kCurrentDirectory;

   return new_path;
 }

 FilePath FilePath::BaseName() const {
   FilePath new_path(path_);
   new_path.StripTrailingSeparatorsInternal();

   // The drive letter, if any, is always stripped.
   StringType::size_type letter = FindDriveLetter(new_path.path_);
   if (letter != StringType::npos) {
     new_path.path_.erase(0, letter + 1);
   }

   // Keep everything after the final separator, but if the pathname is only
   // one character and it's a separator, leave it alone.
   StringType::size_type last_separator = new_path.path_.find_last_of(
       kSeparators, StringType::npos, kSeparatorsLength - 1);
   if (last_separator != StringType::npos &&
       last_separator < new_path.path_.length() - 1) {
     new_path.path_.erase(0, last_separator + 1);
   }

   return new_path;
 }

 StringType FilePath::Extension() const {
   FilePath base(BaseName());
   const StringType::size_type dot = ExtensionSeparatorPosition(base.path_);
   if (dot == StringType::npos)
     return StringType();

   return base.path_.substr(dot, StringType::npos);
 }

 StringType FilePath::FinalExtension() const {
   FilePath base(BaseName());
   const StringType::size_type dot = FinalExtensionSeparatorPosition(base.path_);
   if (dot == StringType::npos)
     return StringType();

   return base.path_.substr(dot, StringType::npos);
 }

 FilePath FilePath::RemoveExtension() const {
   if (Extension().empty())
     return *this;

   const StringType::size_type dot = ExtensionSeparatorPosition(path_);
   if (dot == StringType::npos)
     return *this;

   return FilePath(path_.substr(0, dot));
 }

 FilePath FilePath::RemoveFinalExtension() const {
   if (FinalExtension().empty())
     return *this;

   const StringType::size_type dot = FinalExtensionSeparatorPosition(path_);
   if (dot == StringType::npos)
     return *this;

   return FilePath(path_.substr(0, dot));
 }

 FilePath FilePath::InsertBeforeExtension(StringPieceType suffix) const {
   if (suffix.empty())
     return FilePath(path_);

   if (IsEmptyOrSpecialCase(BaseName().value()))
     return FilePath();

   StringType ext = Extension();
   StringType ret = RemoveExtension().value();
   ret.append(suffix);
   ret.append(ext);
   return FilePath(ret);
 }

 FilePath FilePath::InsertBeforeExtensionASCII(StringPiece suffix) const {
   DCHECK(IsStringASCII(suffix));
 #if defined(OS_WIN)
   return InsertBeforeExtension(ASCIIToUTF16(suffix));
 #elif defined(OS_POSIX) || defined(OS_FUCHSIA)
   return InsertBeforeExtension(suffix);
 #endif
 }

 FilePath FilePath::AddExtension(StringPieceType extension) const {
   if (IsEmptyOrSpecialCase(BaseName().value()))
     return FilePath();

   // If the new extension is "" or ".", then just return the current FilePath.
   if (extension.empty() ||
       (extension.size() == 1 && extension[0] == kExtensionSeparator))
     return *this;

   StringType str = path_;
   if (extension[0] != kExtensionSeparator &&
       *(str.end() - 1) != kExtensionSeparator) {
     str.append(1, kExtensionSeparator);
   }
   str.append(extension);
   return FilePath(str);
 }

 FilePath FilePath::ReplaceExtension(StringPieceType extension) const {
   if (IsEmptyOrSpecialCase(BaseName().value()))
     return FilePath();

   FilePath no_ext = RemoveExtension();
   // If the new extension is "" or ".", then just remove the current extension.
   if (extension.empty() ||
       (extension.size() == 1 && extension[0] == kExtensionSeparator))
     return no_ext;

   StringType str = no_ext.value();
   if (extension[0] != kExtensionSeparator)
     str.append(1, kExtensionSeparator);
   str.append(extension);
   return FilePath(str);
 }

 FilePath FilePath::Append(StringPieceType component) const {
   StringPieceType appended = component;
   StringType without_nuls;

   StringType::size_type nul_pos = component.find(kStringTerminator);
   if (nul_pos != StringPieceType::npos) {
     without_nuls.assign(component.substr(0, nul_pos));
     appended = StringPieceType(without_nuls);
   }

   DCHECK(!IsPathAbsolute(appended));

   if (path_.compare(kCurrentDirectory) == 0 && !appended.empty()) {
     // Append normally doesn't do any normalization, but as a special case,
     // when appending to kCurrentDirectory, just return a new path for the
     // component argument.  Appending component to kCurrentDirectory would
     // serve no purpose other than needlessly lengthening the path, and
     // it's likely in practice to wind up with FilePath objects containing
     // only kCurrentDirectory when calling DirName on a single relative path
     // component.
     return FilePath(appended);
   }

   FilePath new_path(path_);
   new_path.StripTrailingSeparatorsInternal();

   // Don't append a separator if the path is empty (indicating the current
   // directory) or if the path component is empty (indicating nothing to
   // append).
   if (!appended.empty() && !new_path.path_.empty()) {
     // Don't append a separator if the path still ends with a trailing
     // separator after stripping (indicating the root directory).
     if (!IsSeparator(new_path.path_.back())) {
       // Don't append a separator if the path is just a drive letter.
       if (FindDriveLetter(new_path.path_) + 1 != new_path.path_.length()) {
         new_path.path_.append(1, kSeparators[0]);
       }
     }
   }

   new_path.path_.append(appended);
   return new_path;
 }

 FilePath FilePath::Append(const FilePath& component) const {
   return Append(component.value());
 }

 FilePath FilePath::AppendASCII(StringPiece component) const {
   DCHECK(base::IsStringASCII(component));
 #if defined(OS_WIN)
   return Append(ASCIIToUTF16(component));
 #elif defined(OS_POSIX) || defined(OS_FUCHSIA)
   return Append(component);
 #endif
 }

 bool FilePath::IsAbsolute() const {
   return IsPathAbsolute(path_);
 }

 bool FilePath::EndsWithSeparator() const {
   if (empty())
     return false;
   return IsSeparator(path_.back());
 }

 FilePath FilePath::AsEndingWithSeparator() const {
   if (EndsWithSeparator() || path_.empty())
     return *this;

   StringType path_str;
   path_str.reserve(path_.length() + 1);  // Only allocate string once.

   path_str = path_;
   path_str.append(&kSeparators[0], 1);
   return FilePath(path_str);
 }

 FilePath FilePath::StripTrailingSeparators() const {
   FilePath new_path(path_);
   new_path.StripTrailingSeparatorsInternal();

   return new_path;
 }

 bool FilePath::ReferencesParent() const {
   if (path_.find(kParentDirectory) == StringType::npos) {
     // GetComponents is quite expensive, so avoid calling it in the majority
     // of cases where there isn't a kParentDirectory anywhere in the path.
     return false;
   }

   std::vector<StringType> components;
   GetComponents(&components);

   std::vector<StringType>::const_iterator it = components.begin();
   for (; it != components.end(); ++it) {
     const StringType& component = *it;
     // Windows has odd, undocumented behavior with path components containing
     // only whitespace and . characters. So, if all we see is . and
     // whitespace, then we treat any .. sequence as referencing parent.
     // For simplicity we enforce this on all platforms.
     if (component.find_first_not_of(FILE_PATH_LITERAL(". \n\r\t")) ==
             std::string::npos &&
         component.find(kParentDirectory) != std::string::npos) {
       return true;
     }
   }
   return false;
 }

 #if defined(OS_WIN)

 string16 FilePath::LossyDisplayName() const {
   return path_;
 }

 std::string FilePath::MaybeAsASCII() const {
   if (base::IsStringASCII(path_))
     return UTF16ToASCII(path_);
   return std::string();
 }

 std::string FilePath::As8Bit() const {
   return UTF16ToUTF8(value());
 }

 #elif defined(OS_POSIX) || defined(OS_FUCHSIA)

 // See file_path.h for a discussion of the encoding of paths on POSIX
 // platforms.  These encoding conversion functions are not quite correct.

 std::string FilePath::MaybeAsASCII() const {
   if (base::IsStringASCII(path_))
     return path_;
   return std::string();
 }

 std::string FilePath::As8Bit() const {
   return value();
 }

 #endif  // defined(OS_WIN)

 void FilePath::StripTrailingSeparatorsInternal() {
   // If there is no drive letter, start will be 1, which will prevent stripping
   // the leading separator if there is only one separator.  If there is a drive
   // letter, start will be set appropriately to prevent stripping the first
   // separator following the drive letter, if a separator immediately follows
   // the drive letter.
   StringType::size_type start = FindDriveLetter(path_) + 2;

   StringType::size_type last_stripped = StringType::npos;
   for (StringType::size_type pos = path_.length();
        pos > start && IsSeparator(path_[pos - 1]); --pos) {
     // If the string only has two separators and they're at the beginning,
     // don't strip them, unless the string began with more than two separators.
     if (pos != start + 1 || last_stripped == start + 2 ||
         !IsSeparator(path_[start - 1])) {
       path_.resize(pos - 1);
       last_stripped = pos;
     }
   }
 }

 FilePath FilePath::NormalizePathSeparators() const {
   return NormalizePathSeparatorsTo(kSeparators[0]);
 }

 FilePath FilePath::NormalizePathSeparatorsTo(CharType separator) const {
 #if defined(FILE_PATH_USES_WIN_SEPARATORS)
   DCHECK_NE(kSeparators + kSeparatorsLength,
             std::find(kSeparators, kSeparators + kSeparatorsLength, separator));
   StringType copy = path_;
   for (size_t i = 0; i < kSeparatorsLength; ++i) {
     std::replace(copy.begin(), copy.end(), kSeparators[i], separator);
   }
   return FilePath(copy);
 #else
   return *this;
 #endif
 }

 }  // namespace base
	// Copyright (c) 2012 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "base/files/file_path.h"

	#include <string.h>
	#include <algorithm>

	#include "base/logging.h"
	#include "base/macros.h"
	#include "base/strings/string_piece.h"
	#include "base/strings/string_util.h"
	#include "base/strings/utf_string_conversions.h"
	#include "util/build_config.h"

	#if defined(OS_MACOSX)
	#include "base/mac/scoped_cftyperef.h"
	#include "base/third_party/icu/icu_utf.h"
	#endif

	#if defined(OS_WIN)
	#include <windows.h>
	#elif defined(OS_MACOSX)
	#include <CoreFoundation/CoreFoundation.h>
	#endif

	namespace base {

	using StringType = FilePath::StringType;
	using StringPieceType = FilePath::StringPieceType;

	namespace {

	const char* const kCommonDoubleExtensionSuffixes[] = {"gz", "z", "bz2", "bz"};
	const char* const kCommonDoubleExtensions[] = {"user.js"};

	const FilePath::CharType kStringTerminator = FILE_PATH_LITERAL('\0');

	// If this FilePath contains a drive letter specification, returns the
	// position of the last character of the drive letter specification,
	// otherwise returns npos. This can only be true on Windows, when a pathname
	// begins with a letter followed by a colon. On other platforms, this always
	// returns npos.
	StringPieceType::size_type FindDriveLetter(StringPieceType path) {
	#if defined(FILE_PATH_USES_DRIVE_LETTERS)
	// This is dependent on an ASCII-based character set, but that's a
	// reasonable assumption. iswalpha can be too inclusive here.
	if (path.length() >= 2 && path[1] == L':' &&
	((path[0] >= L'A' && path[0] <= L'Z') \|\|
	(path[0] >= L'a' && path[0] <= L'z'))) {
	return 1;
	}
	#endif // FILE_PATH_USES_DRIVE_LETTERS
	return StringType::npos;
	}

	#if defined(FILE_PATH_USES_DRIVE_LETTERS)
	bool EqualDriveLetterCaseInsensitive(StringPieceType a, StringPieceType b) {
	size_t a_letter_pos = FindDriveLetter(a);
	size_t b_letter_pos = FindDriveLetter(b);

	if (a_letter_pos == StringType::npos \|\| b_letter_pos == StringType::npos)
	return a == b;

	StringPieceType a_letter(a.substr(0, a_letter_pos + 1));
	StringPieceType b_letter(b.substr(0, b_letter_pos + 1));
	if (!StartsWith(a_letter, b_letter, CompareCase::INSENSITIVE_ASCII))
	return false;

	StringPieceType a_rest(a.substr(a_letter_pos + 1));
	StringPieceType b_rest(b.substr(b_letter_pos + 1));
	return a_rest == b_rest;
	}
	#endif // defined(FILE_PATH_USES_DRIVE_LETTERS)

	bool IsPathAbsolute(StringPieceType path) {
	#if defined(FILE_PATH_USES_DRIVE_LETTERS)
	StringType::size_type letter = FindDriveLetter(path);
	if (letter != StringType::npos) {
	// Look for a separator right after the drive specification.
	return path.length() > letter + 1 &&
	FilePath::IsSeparator(path[letter + 1]);
	}
	// Look for a pair of leading separators.
	return path.length() > 1 && FilePath::IsSeparator(path[0]) &&
	FilePath::IsSeparator(path[1]);
	#else // FILE_PATH_USES_DRIVE_LETTERS
	// Look for a separator in the first position.
	return path.length() > 0 && FilePath::IsSeparator(path[0]);
	#endif // FILE_PATH_USES_DRIVE_LETTERS
	}

	bool AreAllSeparators(const StringType& input) {
	for (StringType::const_iterator it = input.begin(); it != input.end(); ++it) {
	if (!FilePath::IsSeparator(*it))
	return false;
	}

	return true;
	}

	// Find the position of the '.' that separates the extension from the rest
	// of the file name. The position is relative to BaseName(), not value().
	// Returns npos if it can't find an extension.
	StringType::size_type FinalExtensionSeparatorPosition(const StringType& path) {
	// Special case "." and ".."
	if (path == FilePath::kCurrentDirectory \|\| path == FilePath::kParentDirectory)
	return StringType::npos;

	return path.rfind(FilePath::kExtensionSeparator);
	}

	// Same as above, but allow a second extension component of up to 4
	// characters when the rightmost extension component is a common double
	// extension (gz, bz2, Z). For example, foo.tar.gz or foo.tar.Z would have
	// extension components of '.tar.gz' and '.tar.Z' respectively.
	StringType::size_type ExtensionSeparatorPosition(const StringType& path) {
	const StringType::size_type last_dot = FinalExtensionSeparatorPosition(path);

	// No extension, or the extension is the whole filename.
	if (last_dot == StringType::npos \|\| last_dot == 0U)
	return last_dot;

	const StringType::size_type penultimate_dot =
	path.rfind(FilePath::kExtensionSeparator, last_dot - 1);
	const StringType::size_type last_separator = path.find_last_of(
	FilePath::kSeparators, last_dot - 1, FilePath::kSeparatorsLength - 1);

	if (penultimate_dot == StringType::npos \|\|
	(last_separator != StringType::npos &&
	penultimate_dot < last_separator)) {
	return last_dot;
	}

	for (size_t i = 0; i < arraysize(kCommonDoubleExtensions); ++i) {
	StringType extension(path, penultimate_dot + 1);
	if (LowerCaseEqualsASCII(extension, kCommonDoubleExtensions[i]))
	return penultimate_dot;
	}

	StringType extension(path, last_dot + 1);
	for (size_t i = 0; i < arraysize(kCommonDoubleExtensionSuffixes); ++i) {
	if (LowerCaseEqualsASCII(extension, kCommonDoubleExtensionSuffixes[i])) {
	if ((last_dot - penultimate_dot) <= 5U &&
	(last_dot - penultimate_dot) > 1U) {
	return penultimate_dot;
	}
	}
	}

	return last_dot;
	}

	// Returns true if path is "", ".", or "..".
	bool IsEmptyOrSpecialCase(const StringType& path) {
	// Special cases "", ".", and ".."
	if (path.empty() \|\| path == FilePath::kCurrentDirectory \|\|
	path == FilePath::kParentDirectory) {
	return true;
	}

	return false;
	}

	} // namespace

	FilePath::FilePath() = default;

	FilePath::FilePath(const FilePath& that) = default;
	FilePath::FilePath(FilePath&& that) noexcept = default;

	FilePath::FilePath(StringPieceType path) {
	path_.assign(path);
	StringType::size_type nul_pos = path_.find(kStringTerminator);
	if (nul_pos != StringType::npos)
	path_.erase(nul_pos, StringType::npos);
	}

	FilePath::~FilePath() = default;

	FilePath& FilePath::operator=(const FilePath& that) = default;

	FilePath& FilePath::operator=(FilePath&& that) = default;

	bool FilePath::operator==(const FilePath& that) const {
	#if defined(FILE_PATH_USES_DRIVE_LETTERS)
	return EqualDriveLetterCaseInsensitive(this->path_, that.path_);
	#else // defined(FILE_PATH_USES_DRIVE_LETTERS)
	return path_ == that.path_;
	#endif // defined(FILE_PATH_USES_DRIVE_LETTERS)
	}

	bool FilePath::operator!=(const FilePath& that) const {
	#if defined(FILE_PATH_USES_DRIVE_LETTERS)
	return !EqualDriveLetterCaseInsensitive(this->path_, that.path_);
	#else // defined(FILE_PATH_USES_DRIVE_LETTERS)
	return path_ != that.path_;
	#endif // defined(FILE_PATH_USES_DRIVE_LETTERS)
	}

	// static
	bool FilePath::IsSeparator(CharType character) {
	for (size_t i = 0; i < kSeparatorsLength - 1; ++i) {
	if (character == kSeparators[i]) {
	return true;
	}
	}

	return false;
	}

	void FilePath::GetComponents(std::vector<StringType>* components) const {
	DCHECK(components);
	if (!components)
	return;
	components->clear();
	if (value().empty())
	return;

	std::vector<StringType> ret_val;
	FilePath current = *this;
	FilePath base;

	// Capture path components.
	while (current != current.DirName()) {
	base = current.BaseName();
	if (!AreAllSeparators(base.value()))
	ret_val.push_back(base.value());
	current = current.DirName();
	}

	// Capture root, if any.
	base = current.BaseName();
	if (!base.value().empty() && base.value() != kCurrentDirectory)
	ret_val.push_back(current.BaseName().value());

	// Capture drive letter, if any.
	FilePath dir = current.DirName();
	StringType::size_type letter = FindDriveLetter(dir.value());
	if (letter != StringType::npos) {
	ret_val.push_back(StringType(dir.value(), 0, letter + 1));
	}

	*components = std::vector<StringType>(ret_val.rbegin(), ret_val.rend());
	}

	bool FilePath::IsParent(const FilePath& child) const {
	return AppendRelativePath(child, nullptr);
	}

	bool FilePath::AppendRelativePath(const FilePath& child, FilePath* path) const {
	std::vector<StringType> parent_components;
	std::vector<StringType> child_components;
	GetComponents(&parent_components);
	child.GetComponents(&child_components);

	if (parent_components.empty() \|\|
	parent_components.size() >= child_components.size())
	return false;

	std::vector<StringType>::const_iterator parent_comp =
	parent_components.begin();
	std::vector<StringType>::const_iterator child_comp = child_components.begin();

	#if defined(FILE_PATH_USES_DRIVE_LETTERS)
	// Windows can access case sensitive filesystems, so component
	// comparisions must be case sensitive, but drive letters are
	// never case sensitive.
	if ((FindDriveLetter(*parent_comp) != StringType::npos) &&
	(FindDriveLetter(*child_comp) != StringType::npos)) {
	if (!StartsWith(parent_comp, child_comp, CompareCase::INSENSITIVE_ASCII))
	return false;
	++parent_comp;
	++child_comp;
	}
	#endif // defined(FILE_PATH_USES_DRIVE_LETTERS)

	while (parent_comp != parent_components.end()) {
	if (parent_comp != child_comp)
	return false;
	++parent_comp;
	++child_comp;
	}

	if (path != nullptr) {
	for (; child_comp != child_components.end(); ++child_comp) {
	path = path->Append(child_comp);
	}
	}
	return true;
	}

	// libgen's dirname and basename aren't guaranteed to be thread-safe and aren't
	// guaranteed to not modify their input strings, and in fact are implemented
	// differently in this regard on different platforms. Don't use them, but
	// adhere to their behavior.
	FilePath FilePath::DirName() const {
	FilePath new_path(path_);
	new_path.StripTrailingSeparatorsInternal();

	// The drive letter, if any, always needs to remain in the output. If there
	// is no drive letter, as will always be the case on platforms which do not
	// support drive letters, letter will be npos, or -1, so the comparisons and
	// resizes below using letter will still be valid.
	StringType::size_type letter = FindDriveLetter(new_path.path_);

	StringType::size_type last_separator = new_path.path_.find_last_of(
	kSeparators, StringType::npos, kSeparatorsLength - 1);
	if (last_separator == StringType::npos) {
	// path_ is in the current directory.
	new_path.path_.resize(letter + 1);
	} else if (last_separator == letter + 1) {
	// path_ is in the root directory.
	new_path.path_.resize(letter + 2);
	} else if (last_separator == letter + 2 &&
	IsSeparator(new_path.path_[letter + 1])) {
	// path_ is in "//" (possibly with a drive letter); leave the double
	// separator intact indicating alternate root.
	new_path.path_.resize(letter + 3);
	} else if (last_separator != 0) {
	// path_ is somewhere else, trim the basename.
	new_path.path_.resize(last_separator);
	}

	new_path.StripTrailingSeparatorsInternal();
	if (!new_path.path_.length())
	new_path.path_ = kCurrentDirectory;

	return new_path;
	}

	FilePath FilePath::BaseName() const {
	FilePath new_path(path_);
	new_path.StripTrailingSeparatorsInternal();

	// The drive letter, if any, is always stripped.
	StringType::size_type letter = FindDriveLetter(new_path.path_);
	if (letter != StringType::npos) {
	new_path.path_.erase(0, letter + 1);
	}

	// Keep everything after the final separator, but if the pathname is only
	// one character and it's a separator, leave it alone.
	StringType::size_type last_separator = new_path.path_.find_last_of(
	kSeparators, StringType::npos, kSeparatorsLength - 1);
	if (last_separator != StringType::npos &&
	last_separator < new_path.path_.length() - 1) {
	new_path.path_.erase(0, last_separator + 1);
	}

	return new_path;
	}

	StringType FilePath::Extension() const {
	FilePath base(BaseName());
	const StringType::size_type dot = ExtensionSeparatorPosition(base.path_);
	if (dot == StringType::npos)
	return StringType();

	return base.path_.substr(dot, StringType::npos);
	}

	StringType FilePath::FinalExtension() const {
	FilePath base(BaseName());
	const StringType::size_type dot = FinalExtensionSeparatorPosition(base.path_);
	if (dot == StringType::npos)
	return StringType();

	return base.path_.substr(dot, StringType::npos);
	}

	FilePath FilePath::RemoveExtension() const {
	if (Extension().empty())
	return *this;

	const StringType::size_type dot = ExtensionSeparatorPosition(path_);
	if (dot == StringType::npos)
	return *this;

	return FilePath(path_.substr(0, dot));
	}

	FilePath FilePath::RemoveFinalExtension() const {
	if (FinalExtension().empty())
	return *this;

	const StringType::size_type dot = FinalExtensionSeparatorPosition(path_);
	if (dot == StringType::npos)
	return *this;

	return FilePath(path_.substr(0, dot));
	}

	FilePath FilePath::InsertBeforeExtension(StringPieceType suffix) const {
	if (suffix.empty())
	return FilePath(path_);

	if (IsEmptyOrSpecialCase(BaseName().value()))
	return FilePath();

	StringType ext = Extension();
	StringType ret = RemoveExtension().value();
	ret.append(suffix);
	ret.append(ext);
	return FilePath(ret);
	}

	FilePath FilePath::InsertBeforeExtensionASCII(StringPiece suffix) const {
	DCHECK(IsStringASCII(suffix));
	#if defined(OS_WIN)
	return InsertBeforeExtension(ASCIIToUTF16(suffix));
	#elif defined(OS_POSIX) \|\| defined(OS_FUCHSIA)
	return InsertBeforeExtension(suffix);
	#endif
	}

	FilePath FilePath::AddExtension(StringPieceType extension) const {
	if (IsEmptyOrSpecialCase(BaseName().value()))
	return FilePath();

	// If the new extension is "" or ".", then just return the current FilePath.
	if (extension.empty() \|\|
	(extension.size() == 1 && extension[0] == kExtensionSeparator))
	return *this;

	StringType str = path_;
	if (extension[0] != kExtensionSeparator &&
	*(str.end() - 1) != kExtensionSeparator) {
	str.append(1, kExtensionSeparator);
	}
	str.append(extension);
	return FilePath(str);
	}

	FilePath FilePath::ReplaceExtension(StringPieceType extension) const {
	if (IsEmptyOrSpecialCase(BaseName().value()))
	return FilePath();

	FilePath no_ext = RemoveExtension();
	// If the new extension is "" or ".", then just remove the current extension.
	if (extension.empty() \|\|
	(extension.size() == 1 && extension[0] == kExtensionSeparator))
	return no_ext;

	StringType str = no_ext.value();
	if (extension[0] != kExtensionSeparator)
	str.append(1, kExtensionSeparator);
	str.append(extension);
	return FilePath(str);
	}

	FilePath FilePath::Append(StringPieceType component) const {
	StringPieceType appended = component;
	StringType without_nuls;

	StringType::size_type nul_pos = component.find(kStringTerminator);
	if (nul_pos != StringPieceType::npos) {
	without_nuls.assign(component.substr(0, nul_pos));
	appended = StringPieceType(without_nuls);
	}

	DCHECK(!IsPathAbsolute(appended));

	if (path_.compare(kCurrentDirectory) == 0 && !appended.empty()) {
	// Append normally doesn't do any normalization, but as a special case,
	// when appending to kCurrentDirectory, just return a new path for the
	// component argument. Appending component to kCurrentDirectory would
	// serve no purpose other than needlessly lengthening the path, and
	// it's likely in practice to wind up with FilePath objects containing
	// only kCurrentDirectory when calling DirName on a single relative path
	// component.
	return FilePath(appended);
	}

	FilePath new_path(path_);
	new_path.StripTrailingSeparatorsInternal();

	// Don't append a separator if the path is empty (indicating the current
	// directory) or if the path component is empty (indicating nothing to
	// append).
	if (!appended.empty() && !new_path.path_.empty()) {
	// Don't append a separator if the path still ends with a trailing
	// separator after stripping (indicating the root directory).
	if (!IsSeparator(new_path.path_.back())) {
	// Don't append a separator if the path is just a drive letter.
	if (FindDriveLetter(new_path.path_) + 1 != new_path.path_.length()) {
	new_path.path_.append(1, kSeparators[0]);
	}
	}
	}

	new_path.path_.append(appended);
	return new_path;
	}

	FilePath FilePath::Append(const FilePath& component) const {
	return Append(component.value());
	}

	FilePath FilePath::AppendASCII(StringPiece component) const {
	DCHECK(base::IsStringASCII(component));
	#if defined(OS_WIN)
	return Append(ASCIIToUTF16(component));
	#elif defined(OS_POSIX) \|\| defined(OS_FUCHSIA)
	return Append(component);
	#endif
	}

	bool FilePath::IsAbsolute() const {
	return IsPathAbsolute(path_);
	}

	bool FilePath::EndsWithSeparator() const {
	if (empty())
	return false;
	return IsSeparator(path_.back());
	}

	FilePath FilePath::AsEndingWithSeparator() const {
	if (EndsWithSeparator() \|\| path_.empty())
	return *this;

	StringType path_str;
	path_str.reserve(path_.length() + 1); // Only allocate string once.

	path_str = path_;
	path_str.append(&kSeparators[0], 1);
	return FilePath(path_str);
	}

	FilePath FilePath::StripTrailingSeparators() const {
	FilePath new_path(path_);
	new_path.StripTrailingSeparatorsInternal();

	return new_path;
	}

	bool FilePath::ReferencesParent() const {
	if (path_.find(kParentDirectory) == StringType::npos) {
	// GetComponents is quite expensive, so avoid calling it in the majority
	// of cases where there isn't a kParentDirectory anywhere in the path.
	return false;
	}

	std::vector<StringType> components;
	GetComponents(&components);

	std::vector<StringType>::const_iterator it = components.begin();
	for (; it != components.end(); ++it) {
	const StringType& component = *it;
	// Windows has odd, undocumented behavior with path components containing
	// only whitespace and . characters. So, if all we see is . and
	// whitespace, then we treat any .. sequence as referencing parent.
	// For simplicity we enforce this on all platforms.
	if (component.find_first_not_of(FILE_PATH_LITERAL(". \n\r\t")) ==
	std::string::npos &&
	component.find(kParentDirectory) != std::string::npos) {
	return true;
	}
	}
	return false;
	}

	#if defined(OS_WIN)

	string16 FilePath::LossyDisplayName() const {
	return path_;
	}

	std::string FilePath::MaybeAsASCII() const {
	if (base::IsStringASCII(path_))
	return UTF16ToASCII(path_);
	return std::string();
	}

	std::string FilePath::As8Bit() const {
	return UTF16ToUTF8(value());
	}

	#elif defined(OS_POSIX) \|\| defined(OS_FUCHSIA)

	// See file_path.h for a discussion of the encoding of paths on POSIX
	// platforms. These encoding conversion functions are not quite correct.

	std::string FilePath::MaybeAsASCII() const {
	if (base::IsStringASCII(path_))
	return path_;
	return std::string();
	}

	std::string FilePath::As8Bit() const {
	return value();
	}

	#endif // defined(OS_WIN)

	void FilePath::StripTrailingSeparatorsInternal() {
	// If there is no drive letter, start will be 1, which will prevent stripping
	// the leading separator if there is only one separator. If there is a drive
	// letter, start will be set appropriately to prevent stripping the first
	// separator following the drive letter, if a separator immediately follows
	// the drive letter.
	StringType::size_type start = FindDriveLetter(path_) + 2;

	StringType::size_type last_stripped = StringType::npos;
	for (StringType::size_type pos = path_.length();
	pos > start && IsSeparator(path_[pos - 1]); --pos) {
	// If the string only has two separators and they're at the beginning,
	// don't strip them, unless the string began with more than two separators.
	if (pos != start + 1 \|\| last_stripped == start + 2 \|\|
	!IsSeparator(path_[start - 1])) {
	path_.resize(pos - 1);
	last_stripped = pos;
	}
	}
	}

	FilePath FilePath::NormalizePathSeparators() const {
	return NormalizePathSeparatorsTo(kSeparators[0]);
	}

	FilePath FilePath::NormalizePathSeparatorsTo(CharType separator) const {
	#if defined(FILE_PATH_USES_WIN_SEPARATORS)
	DCHECK_NE(kSeparators + kSeparatorsLength,
	std::find(kSeparators, kSeparators + kSeparatorsLength, separator));
	StringType copy = path_;
	for (size_t i = 0; i < kSeparatorsLength; ++i) {
	std::replace(copy.begin(), copy.end(), kSeparators[i], separator);
	}
	return FilePath(copy);
	#else
	return *this;
	#endif
	}

	} // namespace base